DOCSLIB.ORG

Codexml M3 Bluetooth® Modem

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Codexml M3 Bluetooth® Modem Wireless Communication Tools CodeXML M3 Bluetooth® Modem The CodeXML M3 Bluetooth® Modem features a 2.4 GHz wireless transceiv- er which enables reliable communication and Bluetooth® security between Code Readers and a host computer or system that supports Keyboard, USB or Serial input. The CodeXML M3 Bluetooth® Modem is a simple hardware solution for customers who wish to enjoy the benefits of wireless data collection without modifying existing applications or installing software. Simply plug the modem into your computer and the unit is ready. There is no need to load any drivers (including Bluetooth drivers). CodeXML M3 Bluetooth® Modem firmware is easily upgradable. The modem supports Bluetooth® specification 2.0 + EDR which is a proven, reliable method for replacing cables with secure wireless communications in a wide variety of devices. The features of adaptive frequency hopping and rapid creation of new connections provide unsurpassed efficiencies in wireless data operations when co-sited with 802.11x systems. The CodeXML M3 Bluetooth® Modem is compatible with three Code Readers simultaneously. Features & Benefi ts Security set-up is quick and easy. The modem uses an 8- Modem Features & Benefi ts: digit encryption key which can be user-defined. With every connection Bluetooth® specification 2.0 + EDR authenticates • Bluetooth® to Keyboard, USB or and encryptes data transmissions. Serial Output • Seamless integration with By simply scanning the QuickConnect code on the modem Code Readers label your reader will automatically connect to the computer or • Simple Installation: Simply plug-in system to which it is assigned. You can begin sending data in the modem and start transmitting seconds. Compatible computer operating systems include: wireless data • Extended Range: Transmit and CR3500 • Windows NT, XP & 2000 receive Bluetooth® signals up to • Linux Applications 100 meters (300 feet) • Programmable Logic Controllers • Mountable to working surfaces • Unix Applications (four drilled holes in casing) • Legacy Terminals • Compatible with three Code Readers • All Other Operating Systems CR2 simultaneously Security Features & Benefi ts: Contact a Code representative at (801) 495-2200, or by email • 128-Bit Bluetooth® Authentication to [email protected] to inquire about the and Encryption CodeXML M3 Bluetooth® Modem. General Specifi cations Case Size 3.2” x 2.75” x 1” high with 4 mounting drilled holes (2 on each side) Note: Use #4 tapered fl athead screws when securing modem Frequency 2.4 GHZ - ISM band Bluetooth Class CodeXML M3 Bluetooth® Modem contains Class I Bluetooth Radio; Communicates with Class I, II or III Bluetooth Radios Emission Type Frequency hopping spread spectrum (FHSS GFSK) RF Data Rate 1 Mbps Data Throughput 115 kbps maximum Operating Temperatures 0° to 70° C (commercial) Power Source 5V DC adapter included. USB continuous current draw: Min 57 mAH (connected); Max 100 mAH (searching for connection) Range (Distance) 100 Meters (300 feet) - Line of sight Connectors Note: CodeXML M3 Bluetooth® Modem supports different communication modes. Select necessary modem cable for enabling desired communication method: Serial (DB9) Connection Standard DB9 connector * Power Supply required; Default Baud Rate 9600 (9600-115,200 baud rate capable) cable and power Supply Default Data Bits 8 (7 bits capable) ordered separately Default Parity None (Even, Odd parity capable) Default Stop Bits 1 (2 stop bits capable) Hardware Flow Control None Cable: CR2AG-C1 or CR2AG-C3 USB Connection Standard USB connector for Keyboard Input Settings Include: US English • No Power Supply needed; Keyboard (Leading 0; No Leading 0; or ctrl+char), Alt+Keypad Numbers, French cable ordered separately Keyboard, German Keyboard, Japanese Keyboard* Cable (6 ft.): CR2AG-C0 * For customized settings, minimum quantities and lead times may apply. Cable (12 ft.): CR2AG-C20 Antenna Embedded (internal) antenna Bluetooth Device V2.0 +EDR ; SPP (Serial Port Profi le) - Slave Security • 128-bit encryption key • User-defi ned encryption key option • CodeXML M3 Bluetooth® Modem QuickConnect Code feature pairs reader to host computer or system phone: (801) 495-2200 fax: (801) 495-2202 Specifications subject to change web: www.codecorp.com without notice. C003903_02 09/08 © 2008 Code Corporation. All rights reserved. US Patent: US 7,240,831, Patents Pending.
Load more

Recommended publications
  • TITAN 2000 - Cat 12/15 4G LTE CPE Advanced Modem
    TITAN 2000 - Cat 12/15 4G LTE CPE Advanced Modem Global Telecom’s TITAN 2000 is the latest advancement in modems for the Internet of Things. With 8x8 MIMO at its core, the TITAN 2000 provides lightning fast speed and always reliable connections for enterprise and consumers alike. The TITAN 2000 is capable of maximum download speeds of 600 MBPS and is built using a Cat 15 module (model: Global-7243A) with eight antenna ports. It delivers 11 dB, which is 13 times stronger than typical 2x2 MIMO modems or end user devices. This high capacity and strong received power comes from specialized design with high MIMO and high gain antenna configuration. It’s an ideal solution for homes and businesses looking to truly cut the cord once and for all. Innovation and rapid changes in our connected devices make it hard to plan for § PoE capable for simple the future, but the TITAN 2000’s designers have taken migration needs into and reliable interface account. Using cellular high-speed protocols, including advanced LTE and 5G, § Advanced 4G the TITAN 2000 has been created to be future-proof and capable of hosting Cat capabilities with 8R2T 19 and 5G modules with pin-to-pin compatibility -- eliminating the need to design (Release 13 change software or other parts. Global Telecom’s flagship product for 2020 compliant) also supports up to four channels of carrier aggregation utilizing inter- and intra- band. The TITAN 2000 is compatible with all U.S. carriers and in more than 165 § Multi-band and multi- countries worldwide.
    [Show full text]
  • Components Selection Guide for Bluetooth® Low Energy
    Application Guide Components Selection Guide for Bluetooth® Low Energy Optimize designs, reduce time to market Ceramic Capacitors RF Inductors Power Inductors Timing Devices Bluetooth® Low Energy (BLE) is the next generation Bluetooth® release since version 4.0. Its low power consumption feature makes the BLE a popular choice across many applications. Knowledge of selecting the appropriate peripheral components greatly reduces design time and improves efficiency. System on Chip Power Inductor Battery DC/DC Antenna (Li/Coin Battery) Converter Wireless Ceramic Processor Communication Capacitor Memory (2.4GHz) RF Inductor Timing Devices Sensor Block diagram / Peripheral components Market / applications • IoT devices: Beacon, sensing device with wireless communication • Healthcare: Medical IoT devices, insulin pen, continuous glucose monitoring (CGM), medical tester, portable and personal devices • Industrial: Factory automation (FA), item tracking, monitoring Content Ceramic capacitors .................................. 3 Crystal units ............................................... 7 Ceramic capacitors .................................. 4 MEMS resonators ..................................... 8 RF inductors ............................................... 5 Design tools ................................................ 9 Power inductors ........................................ 6 Global locations ..................................... 10 2 Contents are subject to change without notice. © November 2020 Murata Manufacturing Co., Ltd. • BLE Component
    [Show full text]
  • Hughesnet HT2000W Satellite Modem – User Guide
    HT2000W Satellite Modem User Guide 1041264-0001 Revision A February 15, 2017 11717 Exploration Lane, Germantown, MD 20876 Phone (301) 428-5500 Fax (301) 428-1868/2830 Copyright © 2017 Hughes Network Systems, LLC All rights reserved. This publication and its contents are proprietary to Hughes Network Systems, LLC. No part of this publication may be reproduced in any form or by any means without the written permission of Hughes Network Systems, LLC, 11717 Exploration Lane, Germantown, Maryland 20876. Hughes Network Systems, LLC has made every effort to ensure the correctness and completeness of the material in this document. Hughes Network Systems, LLC shall not be liable for errors contained herein. The information in this document is subject to change without notice. Hughes Network Systems, LLC makes no warranty of any kind with regard to this material, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose. Trademarks HUGHES and Hughes Network Systems are trademarks of Hughes Network Systems, LLC. All other trademarks are the property of their respective owners. Contents Contents ................................................................................................. 3 Understanding safety alert messages .................................................... 5 Messages concerning personal injury .................................................................... 5 Messages concerning property damage ................................................................ 5 Safety
    [Show full text]
  • Glossary of Terminology
    Glossary of Broadband Terminology This glossary was compiled by Ray Elseth of Broadband Development 3 (http://www.bbd3.com) and Thomas Asp of Virchow Krause (http://virchowkrause.com), and is a supplement to “Broadband Access: The Local Government Role” by Thomas Asp, Harvey L. Reiter, Jerry Schulz, and Ronald L. Vaden (IQ Report 36, no. 2 [Washington, D.C.: ICMA, 2004]). 802.11 A family of specifications covering wireless connectivity between devices normally located within 100’ to 300’ of each other. Often referred to as Wireless Local Area Network (WLAN). Most common implementation is 802.11b (see Wi- Fi), but 802.11a and 802.11g are also in active use. 802.15 A family of specifications covering wireless connectivity between devices normally located within 10’ to 30’ of each other. Often referred to as Wireless Personal Area Network (WPAN). Implemented as “Bluetooth.” 802.16 A family of specifications covering wireless connectivity between devices normally located within 1 to 30 miles of each other. Often referred to as Wireless Metropolitan Area Network (WMAN). Access Point (AP) A hardware device that acts as a connectivity hub to permit users of a wireless device to connect to a wired local area network. Provides a bridge between Ethernet wired LANs (local area networks) and the wireless network. Access points are the connectivity point between Ethernet wired networks and devices equipped with a wireless LAN adapter card. Antenna The equipment that allows the transmission or reception of radio frequency energy. Asynchronous Digital A technology that allows high-speed data to be sent over a Subscriber Line single pair of existing copper telephone lines, with data rates (ADSL) for receiving data differing from data rates for sending data.
    [Show full text]
  • QUESTION 20-1/2 Examination of Access Technologies for Broadband Communications
    International Telecommunication Union QUESTION 20-1/2 Examination of access technologies for broadband communications ITU-D STUDY GROUP 2 3rd STUDY PERIOD (2002-2006) Report on broadband access technologies eport on broadband access technologies QUESTION 20-1/2 R International Telecommunication Union ITU-D THE STUDY GROUPS OF ITU-D The ITU-D Study Groups were set up in accordance with Resolutions 2 of the World Tele- communication Development Conference (WTDC) held in Buenos Aires, Argentina, in 1994. For the period 2002-2006, Study Group 1 is entrusted with the study of seven Questions in the field of telecommunication development strategies and policies. Study Group 2 is entrusted with the study of eleven Questions in the field of development and management of telecommunication services and networks. For this period, in order to respond as quickly as possible to the concerns of developing countries, instead of being approved during the WTDC, the output of each Question is published as and when it is ready. For further information: Please contact Ms Alessandra PILERI Telecommunication Development Bureau (BDT) ITU Place des Nations CH-1211 GENEVA 20 Switzerland Telephone: +41 22 730 6698 Fax: +41 22 730 5484 E-mail: [email protected] Free download: www.itu.int/ITU-D/study_groups/index.html Electronic Bookshop of ITU: www.itu.int/publications © ITU 2006 All rights reserved. No part of this publication may be reproduced, by any means whatsoever, without the prior written permission of ITU. International Telecommunication Union QUESTION 20-1/2 Examination of access technologies for broadband communications ITU-D STUDY GROUP 2 3rd STUDY PERIOD (2002-2006) Report on broadband access technologies DISCLAIMER This report has been prepared by many volunteers from different Administrations and companies.
    [Show full text]
  • Internet Connection Sharing Quick Setup Guide
    Internet Connection Sharing with your Pocket PC over Bluetooth, by Belkin Internet Connection Sharing Quick Setup Guide For HP IPAQ Pocket PC Models: H1940, H1945, H2210, H2215, H5450, H5455, H5550, H5555 also works with other Pocket PCs using Widcomm BTCE ver.1.3.x Use with Belkin Bluetooth PC Adapters: F8T001, F8T002 and F8T003 Internet Connection Sharing with your Pocket PC over Bluetooth, by Belkin Note: Please be sure to enable Internet Connection Sharing on your Windows PC before you begin this guide. Please refer to your Windows Help for more information on Internet Connection Sharing. SECTION 1: Pairing your Pocket PC to your Computer Step 1: Tap on the Bluetooth icon located in the lower right corner of the Today Screen. Select Bluetooth Manager. Note: Be sure that your Bluetooth Radio is turned ON. Step 2: Tap on the Tools located in the menu bar located at the bottom of your screen. Then select Paired Devices. Internet Connection Sharing with your Pocket PC over Bluetooth, by Belkin Step 3: Tap on the Add button. Step 4: Tap on Search icon located to the right of the Device text box. This will begin a search for all Bluetooth devices in your area. Internet Connection Sharing with your Pocket PC over Bluetooth, by Belkin Step 5: Tap on the devices you would like to establish a connection for your Pocket PC. Step 6: Enter a Passkey in the Passkey Text Box and tap “OK”. For example “0000” or “1234.” The passkey could be any alphanumeric number you want. Internet Connection Sharing with your Pocket PC over Bluetooth, by Belkin Step 7: Check your Computer.
    [Show full text]
  • Iot Systems Overview
    IoT systems overview CoE Training on Traffic engineering and advanced wireless network planning Sami TABBANE 30 September -03 October 2019 Bangkok, Thailand 1 Objectives •Present the different IoT systems and their classifications 2 Summary I. Introduction II. IoT Technologies A. Fixed & Short Range B. Long Range technologies 1. Non 3GPP Standards (LPWAN) 2. 3GPP Standards IoT Specificities versus Cellular IoT communications are or should be: Low cost , Low power , Long battery duration , High number of connections , Low bitrate , Long range , Low processing capacity , Low storage capacity , Small size devices , Relaxed latency , Simple network architecture and protocols . IoT Main Characteristics Low power , Low cost (network and end devices), Short range (first type of technologies) or Long range (second type of technologies), Low bit rate (≠ broadband!), Long battery duration (years), Located in any area (deep indoor, desert, urban areas, moving vehicles …) Low cost 3GPP Rel.8 Cost 75% 3GPP Rel.8 CAT-4 20% 3GPP Rel.13 CAT-1 10% 3GPP Rel.13 CAT-M1 NB IoT Complexity Extended coverage +20dB +15 dB GPRS CAT-M1 NB-IoT IoT Specificities IoT Specificities and Impacts on Network planning and design Characteristics Impact • High sensitivity (Gateways and end-devices with a typical sensitivity around -150 dBm/-125 dBm with Bluetooth/-95 dBm in 2G/3G/4G) Low power and • Low frequencies strong signal penetration Wide Range • Narrow band carriers far greater range of reception • +14 dBm (ETSI in Europe) with the exception of the G3 band with +27 dBm, +30 dBm but for most devices +20 dBm is sufficient (USA) • Low gateways cost Low deployment • Wide range Extended coverage + strong signal penetration and Operational (deep indoor, Rural) Costs • Low numbers of gateways Link budget: UL: 155 dB (or better), DL: Link budget: 153 dB (or better) • Low Power Long Battery life • Idle mode most of the time.
    [Show full text]
  • Digital Subscriber Lines and Cable Modems Digital Subscriber Lines and Cable Modems
    Digital Subscriber Lines and Cable Modems Digital Subscriber Lines and Cable Modems Paul Sabatino, [email protected] This paper details the impact of new advances in residential broadband networking, including ADSL, HDSL, VDSL, RADSL, cable modems. History as well as future trends of these technologies are also addressed. OtherReports on Recent Advances in Networking Back to Raj Jain's Home Page Table of Contents ● 1. Introduction ● 2. DSL Technologies ❍ 2.1 ADSL ■ 2.1.1 Competing Standards ■ 2.1.2 Trends ❍ 2.2 HDSL ❍ 2.3 SDSL ❍ 2.4 VDSL ❍ 2.5 RADSL ❍ 2.6 DSL Comparison Chart ● 3. Cable Modems ❍ 3.1 IEEE 802.14 ❍ 3.2 Model of Operation ● 4. Future Trends ❍ 4.1 Current Trials ● 5. Summary ● 6. Glossary ● 7. References http://www.cis.ohio-state.edu/~jain/cis788-97/rbb/index.htm (1 of 14) [2/7/2000 10:59:54 AM] Digital Subscriber Lines and Cable Modems 1. Introduction The widespread use of the Internet and especially the World Wide Web have opened up a need for high bandwidth network services that can be brought directly to subscriber's homes. These services would provide the needed bandwidth to surf the web at lightning fast speeds and allow new technologies such as video conferencing and video on demand. Currently, Digital Subscriber Line (DSL) and Cable modem technologies look to be the most cost effective and practical methods of delivering broadband network services to the masses. <-- Back to Table of Contents 2. DSL Technologies Digital Subscriber Line A Digital Subscriber Line makes use of the current copper infrastructure to supply broadband services.
    [Show full text]
  • State of the Art in LP-WAN Solutions for Industrial Iot Services
    sensors Review State of the Art in LP-WAN Solutions for Industrial IoT Services Ramon Sanchez-Iborra * and Maria-Dolores Cano Departamento de Tecnologías de la Información y las Comunicaciones, Universidad Politécnica de Cartagena, Cartagena 30202, Spain; [email protected] * Correspondence: [email protected]; Tel.: +34-968-325-953 Academic Editor: Gonzalo Pajares Martinsanz Received: 25 February 2016; Accepted: 9 May 2016; Published: 17 May 2016 Abstract: The emergence of low-cost connected devices is enabling a new wave of sensorization services. These services can be highly leveraged in industrial applications. However, the technologies employed so far for managing this kind of system do not fully cover the strict requirements of industrial networks, especially those regarding energy efficiency. In this article a novel paradigm, called Low-Power Wide Area Networking (LP-WAN), is explored. By means of a cellular-type architecture, LP-WAN–based solutions aim at fulfilling the reliability and efficiency challenges posed by long-term industrial networks. Thus, the most prominent LP-WAN solutions are reviewed, identifying and discussing the pros and cons of each of them. The focus is also on examining the current deployment state of these platforms in Spain. Although LP-WAN systems are at early stages of development, they represent a promising alternative for boosting future industrial IIoT (Industrial Internet of Things) networks and services. Keywords: Low-Power Wide Area Networks (LP-WAN); Machine-to-Machine (M2M) communications; Industrial Internet of Things (IIoT); Internet of Things (IoT); wireless sensor networks 1. Introduction Machine-to-Machine (M2M) networks and Industrial Internet of Things (IIoT) services are two key enabling approaches for future industrial networking [1].
    [Show full text]
  • Long-Range Wireless Radio Technologies: a Survey
    future internet Review Long-Range Wireless Radio Technologies: A Survey Brandon Foubert * and Nathalie Mitton Inria Lille - Nord Europe, 59650 Villeneuve d’Ascq, France; [email protected] * Correspondence: [email protected] Received: 19 December 2019; Accepted: 11 January 2020; Published: 14 January 2020 Abstract: Wireless networks are now a part of the everyday life of many people and are used for many applications. Recently, new technologies that enable low-power and long-range communications have emerged. These technologies, in opposition to more traditional communication technologies rather defined as "short range", allow kilometer-wide wireless communications. Long-range technologies are used to form Low-Power Wide-Area Networks (LPWAN). Many LPWAN technologies are available, and they offer different performances, business models etc., answering different applications’ needs. This makes it hard to find the right tool for a specific use case. In this article, we present a survey about the long-range technologies available presently as well as the technical characteristics they offer. Then we propose a discussion about the energy consumption of each alternative and which one may be most adapted depending on the use case requirements and expectations, as well as guidelines to choose the best suited technology. Keywords: long-range; wireless; IoT; LPWAN; mobile; cellular; LoRa; Sigfox; LTE-M; NB-IoT 1. Introduction Wireless radio technologies, such as Wi-Fi, are used daily to enable inter-device communications. In the last few years, new kinds of wireless technologies have emerged. In opposition to standard wireless technologies referred to as “short-range”, long-range radio technologies allow devices to communicate over kilometers-wide distances at a low energy cost, but at the expense of a low data rate.
    [Show full text]
  • Comparison of the IEEE 802.11, 802.15.1, 802.15.4 and 802.15.6 Wireless Standards
    Comparison of the IEEE 802.11, 802.15.1, 802.15.4 and 802.15.6 wireless standards Jan Magne Tjensvold∗ September 18, 2007 1 Introduction This paper contains a comparison of some of the wireless standards authored by the Institute of Electrical and Electronics Engineers (IEEE) [1]. It explain some of the differences and similarities between the IEEE 802.11, 802.15.1, 802.15.4 and 802.15.6 wireless standards with an emphasis on the physical layer. 2 Wireless standards The wireless standards that we will investigate in this paper is only a selec- tion from all the standards available. These explanations are not meant to be exhaustive. 2.1 IEEE 802.11 - WLAN/Wi-Fi Wireless LAN (WLAN, also known as Wi-Fi) is a set of low tier, terrestrial, net- work technologies for data communication. The WLAN standards operates on the 2.4 GHz and 5 GHz Industrial, Science and Medical (ISM) frequency bands. It is specified by the IEEE 802.11 standard [2] and it comes in many different variations like IEEE 802.11a/b/g/n. The application of WLAN has been most visible in the consumer market where most portable computers support at least one of the variations. 2.2 IEEE 802.15.1 - Bluetooth The IEEE 802.15.1 standard [3] is the basis for the Bluetooth wireless communi- cation technology. Bluetooth is a low tier, ad hoc, terrestrial, wireless standard for short range communication. It is designed for small and low cost devices with low power consumption. The technology operates with three different classes of devices: Class 1, class 2 and class 3 where the range is about 100 meters, 10 meters and 1 meter respectively.
    [Show full text]
  • User Manual MG7315
    User Manual 8x4 Cable Modem plus N450 Wireless Router MG7315 NOTICE This document contains proprietary information protected by copyright, and this Manual and all the accompanying hardware, software, and documentation are copyrighted. No part of this document may be photocopied or reproduced by mechanical, electronic, or other means in any form. The manufacturer does not warrant that the hardware will work properly in all environments and applications, and makes no warranty or representation, either expressed or implied, with respect to the quality, performance, merchantability, or fitness for a particular purpose of the software or documentation. The manufacturer reserves the right to make changes to the hardware, software, and documentation without obligation to notify any person or organization of the revision or change. All brand and product names are the trademarks of their respective owners. © Copyright 2016 MTRLC LLC All rights reserved. SAFETY This equipment is designed with the utmost care for the safety of those who install and use it. However, special attention must be paid to the dangers of electric shock and static electricity when working with electrical equipment. All guidelines of this and of the computer manufacture must therefore be allowed at all times to ensure the safe use of the equipment. CAUTION: • Do not put the cable modem/router in water. • Do not use the cable modem/router outdoors. • Keep the cable modem/router in an environment that is between 0°C and 40°C (between 32°F and 104°F). • Do not place any object on top of the cable modem/router since this may cause overheating.
    [Show full text]